Microinjection of fluorescence dye in a plant cell and its intercellular translocation using a multi-channel microelectrode system

Cell-lytic activity of tobacco BY-2 induced by a fungal elicitor from alternaria alternata attributed to the expression of a class I beta-1,3-glucanase gene

Stress-induced cell-lytic activity was found in tobacco BY-2 cells treated with various stresses. Among 14 stresses, an elicitor fraction isolated from Alternaria alternata showed the highest inducing activity. Cell-lytic activity increased for 72 h even in the control sample, treated with distilled water, and several isozymes of beta-1,3-glucanases and chitinases were found to be involved in it. In contrast, cell-lytic activity in BY-2 cells treated with a fungal elicitor reached a higher level after 60 h. The principal enzymes specifically involved in this stress-induced portion are speculated to be basic beta-1,3-glucanases. A class I beta-1,3-glucanase gene (glu1) was found to be the specific gene for the stress-induced cell-lytic activity. Its expression became observable at 24 h, and the intensity reached a maximum at about 60-72 h. The glu1 was thus assigned as a late gene. Its role in the stress response is discussed in conjunction with earlier genes such as chitinases.

Simultaneous imaging of multiple fluorescent probes in bio-cells

In order to obtain the full spectrum from 400 to 800 nm of each pixel of a microscopic image, a unique spectro-imaging system was developed using an image slicer. The image slicer is composed of 100 photo fibers which are arranged in a matrix of 10 x 10 at the entrance and 100 x 1 at the exit. A line of this 100 signals is passed through a glism and projected onto a CCD. This system was applied to the fluorescent imaging of bio-cells. One of the demonstrative examples was simultaneous measurements of the Ca2+ concentration and the pH using of respective fluorescent probes. An electric signal was applied to BY-2 protoplasts and the fluorescent spectrum from 500 nm to 800 nm was measured every 5 s. The spectrum of the BY-2 protoplasts changed in response to the electric signal and the Ca2+ concentration, and the pH changes could be monitored. The wavelength resolution was satisfactory, but the space resolution was still rough in comparison with the usual microscopic systems. Notwithstanding these conditions, we could obtain discrete data from more than several tens of sites in a single-cell or a chain of several cells.

Single-cell viability assessment with a novel spectro-imaging system

Single-cell viability assessment by means of plural dye probes require the spectral and temporal analysis of microscopic images of the test cells. To meet this requirement, we have developed a simple and compact spectro-imaging system using an image slicer and a grism. The image slicer was made of a bundle of 100 optical fibers. The field of view is divided into 10 x 10 sections. The spectral data of each section could be recorded every 5 s in the range from 400 to 800 nm at 5 nm resolution. The viability changes of yeast or tobacco single-cells were measured with this system. Using BY-2 cells, for example, the response to a chemical stress of saponin was measured by means of two fluorescent probes. The spectral-spatial-temporal data of fluorescein and DNA bound ethidium bromide provided us with useful information about the dynamic change of cell membrane permeability from which the cell viability was assessed.

Effects of a pulsing electric signal on the cross membrane potential and the cell division potentiality of a single cell of tobacco

A pulsing electric signal (pulse width 10 s) was applied to a single cell of cultured tobacco, line BY-2, by inserting a multifunctional microelectrode (MME) into the cell. The electric voltage (V(ET)) was loaded between the electrode terminals of the MME and the reference electrode situated in the extracellular medium. Since the electrical impedance of the MME was as large as that of the cell membrane, the effective potential acting across the cell membrane (V(CMP)) should be only some portion of V(ET). The MME enabled simultaneous measurement of V(ET) and V(CMP). When V(ET) was varied from 0 to -1 V, V(CMP) changed linearly in proportion to V(ET). When V(ET) variation range was enlarged (from 0 to -2 V), V(CMP) changing pattern became a declined curve. When V(ET) variation range was further enlarged (from 0 to -5 V), the V(CMP) changing pattern showed a saturation curve. Under this condition, the cell division potentiality decreased accordingly. Based on these results, the feasibility of V(CMP) as an indicator of the effective intensity of an electric stress signal is discussed. In the present case of a BY-2 cell, a proper intensity of V(CMP) that could cause an appreciable stress and not a lethal signal was estimated as -250 mV.